HZB uses electricity-producing facade wall as real laboratory

Opened! Bernd Rech (l.) and Christian Rickerts (r.) pressed the symbolic red button to start the Real Lab in Adlershof on 6 September.

Opened! Bernd Rech (l.) and Christian Rickerts (r.) pressed the symbolic red button to start the Real Lab in Adlershof on 6 September. © HZB / M. Setzpfandt

Many guests came to the opening and inspected the visually appealing solar facade of the new building.

Many guests came to the opening and inspected the visually appealing solar facade of the new building.

The guest of our podium discussion

The guest of our podium discussion

The architects of the BAIP consulting offcie provide information on the diverse use of building-integrated photovoltaics.

The architects of the BAIP consulting offcie provide information on the diverse use of building-integrated photovoltaics.

In the shine of the sun: The new research building with the solar facade.

In the shine of the sun: The new research building with the solar facade.

In the presence of the State Secretary for Economic Affairs, Energy and Operations of the State of Berlin, Christian Rickerts, the HZB officially commissioned the solar façade of a new research building on 6 September 2021. What makes it so special is that the elegant façade not only generates up to 50 kilowatts of electricity (peak power). It also provides important insights into the behaviour of the solar modules under different weather conditions.  

Solar energy is considered one of the most promising renewable energies. More and more houses have a photovoltaics on the roof and large open-space systems are increasingly being seen. But solar modules can also be integrated in more diverse ways, for example in building facades. Through the solar activation of the entire building envelope, photovoltaics becomes a building element and turns buildings into electricity generators. Moreover, the solar modules can also be integrated in a visually appealing way. For two years now, the HZB-based consulting office for building-integrated Photovoltaics (BAIP) has been providing advice on precisely this topic.

Now the HZB itself is doing the practical test. "For the first time, a complete building with a facade-integrated photovoltaic system is being operated as a real laboratory. The extensive measurement technology enables new insights into the real behaviour of solar modules in a facade in different seasons and weather conditions, over a long period of time," says Dr. Björn Rau, who heads the BAIP office at HZB.

The most important in brief:

  • the real lab consists of 360 CIGS thin-film solar modules installed on three facades (west, south and north sides)
  • Power per module: approx. 135 watts (peak power of the entire facade: just under 50 kilowatts)
  • additional sensor technology (including 72 temperature, 10 irradiation and 4 wind sensors) installed
  • serves for long-term investigation of PV yields as a function of environmental factors (pollution), weather conditions (sun, wind, reflection) and compass directions, etc.
  • Comparison between real data and simulation values of yield forecasts

A special feature is the concealed suspension. It enables a frameless design without additional edging at the edge of the module. This makes it possible to combine the modules ideally with the metal curtain wall of the building. Björn Rau emphasises: "We also deliberately placed value on the design integration of the modules into the building envelope and, with CIGS technology, selected the material system about which there is a very great deal of expertise at HZB." Many research groups at HZB work with CIGS thin films, from materials research to the development of building elements.

The research building: what happens inside

The facade serves as a real laboratory for photovoltaics research, but something completely different happens inside the building: here, researchers develop and build worldwide unique components for BESSY II and other synchrotrons. The building houses a clean room, various laboratories and assembly stations for HZB's internationally renowned accelerator research.

 

red.

  • Copy link

You might also be interested in

  • Perovskite triple-junction solar cells: Even more efficient with GO/SAM bilayers
    Science Highlight
    09.07.2026
    Perovskite triple-junction solar cells: Even more efficient with GO/SAM bilayers
    Perovskite semiconductors efficiently convert sunlight into electrical energy; they are also inexpensive and extremely lightweight. A team at HZB has developed a triple-junction solar cell comprising different perovskite semiconductors, with a novel bilayer of graphene oxide (GO) and a self-assembled monolayer (SAM) as the hole conductor. This bilayer significantly increases both efficiency and long-term stability. The efficiency of the novel perovskite triple-junction solar cell is 27.3% and shows hardly any decline even after more than 770 hours of operation. The study has been published in the renowned journal Joule.
  • Green Deal Ukraїna at the Ukraine Recovery Conference
    News
    09.07.2026
    Green Deal Ukraїna at the Ukraine Recovery Conference
    End of June, the Ukraine Recovery Conference (UCR2026) took place in Gdańsk, Poland. Unlike previous editions, URC2026 introduced a dedicated Energy Platform, jointly organised by the Ministry of Energy of Ukraine and the Ministry of Climate and Environment of Poland, which brought together energy-related discussions, announcements, and side events in one place, increasing the visibility and coordination of key energy topics. Green Deal Ukraїna, an initiative coordinated by HZB, organised three events on the sidelines of URC on research and energy topics as part of the conference.
  • Perovskites: the future of PV? - The smarter-E Podcast
    News
    07.07.2026
    Perovskites: the future of PV? - The smarter-E Podcast
    Perovskites: The Race for the Future of PV?